共查询到20条相似文献,搜索用时 31 毫秒
1.
K. A. W. Crook 《Australian Journal of Earth Sciences》2013,60(1):195-202
Two approaches to the time‐stratigraphic subdivision of the Australian Pre‐cambrian are possible. In one, bodies of rock are referred, by means of radio‐metric dates, to periods defined by chosen points on the absolute time‐scale. In the second, the boundaries of time‐rock units are defined at selected reference points on the ground, and these reference points are dated as accurately as possible by radiometric means. Geographically distant bodies of rock are correlated with “type” time‐rock units by radiometric dates. The second approach is preferred since: (a) it leads to a geological time‐scale homogeneous in concept; (b) it implies that there is no difference in principle between Precambrian and Phanerozoic time‐stratigraphy; and (c) the time‐rock units so created are directly comparable with those that might be established by lithological, palaeontological, magnetometric, or climatic‐litho‐logical correlation. Criteria and procedures for the definition of time‐rock units and their boundaries are suggested. 相似文献
2.
At present, most, if not all zinc is being produced from the mineral sphalerite. With the exception of its piezoelectricity and in some cases its density, sphalerite has no salient physical properties to routinely allow its direct detection by geophysical methods. Although the mineral usually occurs with other sulfides, which do respond to various geophysical techniques, detection of zinc‐bearing deposits is often difficult. In this paper, physical property measurements from numerous, mainly Australian, deposits are presented, together with examples from various geophysical surveys. The results are used to suggest the most effective geophysical technique for the direct detection of the different types of zinc‐bearing deposits. Induced polarisation is probably the most effective technique for unmetamorphosed sediment‐hosted deposits and for carbonate‐hosted deposits, whereas electromagnetics is usually the most appropriate method to use for volcanic‐hosted deposits and for sediment‐hosted deposits that have been strongly metamorphosed. Magnetics is the best technique for skarn and ‘Cobar‐style’ deposits. However, it must be emphasised that usually more than one geophysical technique is required before a prospect can be considered to have been thoroughly explored. 相似文献
3.
We compare two methods of evaluating head covariance for two‐dimensional steady‐state flow in mildly heterogeneous bounded
rectangular aquifers. The quasi‐analytical approach, widely used in stochastic subsurface hydrology, is based on the Green's
function representation, and involves numerical four‐fold integration. We compare this approach with a numerical solution
of the two‐dimensional boundary‐value problem for head covariance. We show that the finite differences integration of this
problem is computationally less expensive than numerical four‐fold integration of slowly‐convergent infinite series.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
4.
K. R. Walker Germaine A. Joplin J. F. Lovering R. Green 《Australian Journal of Earth Sciences》2013,60(2):149-177
With increasing intensity of metamorphism, and particularly metasomatism, it becomes more and more difficult to separate amphibolites in North‐western Queensland into ortho‐ and para‐amphibolites, and a stage is reached at which the two are indistinguishable. Field evidence, carefully sought, has enabled the origin of some apparently identical rocks to be determined, and laboratory methods were applied to these rocks to see if grounds for the separation of amphibolites of unknown origin could be determined. None of the six methods tried — mineralogy (including feldspar twinning), chemical analysis (including TiO2 content), spectrography, rock magnetism — proved to be as successful as the field method in distinguishing the two rock groups; some methods used with apparent success elsewhere, such as feldspar twinning or chemical analyses, are found to be unsuccessful here, which suggests that though the problem is world‐wide, solutions are only of local validity. 相似文献
5.
Bindheimite has been identified in specimens from the Lvov Lease, N.W. Queensland. Chemical, microscopic and X‐ray data are given for the mineral which was found to possess a cubic lattice with a unit cell dimension of 10–427 A. 相似文献
6.
F. E. M. Lilley Merren N. Sloane J. H. Sass 《Australian Journal of Earth Sciences》2013,60(7-8):439-445
A map is presented based on all known Australian heat‐flow estimates, including five new ones. A second map, based on the first, also is presented, but excludes any determinations judged for any reason to be unreliable. The data show that heat flow over large areas of the continent is effectively uniform to within 0.5 heat flow units (i.e. to within 20 mW m‐2), with perhaps three major regional heat‐flow provinces being defined in western, central, and eastern Australia. 相似文献
7.
Potassium‐argon measurements have been carried out on the separated micas of 27 samples, principally granites, from the Mount Isa‐Cloncurry region of north‐western Queensland. There is evidence for at least two tectonic periods within the “Lower Proterozoic” of the area. The first is represented only in the north‐western portion, with ages greater than 1,770 m.y. on the Ewen Granite, and on the granites of the Nicholson River area to the far north‐west. The second at 1,400–1,450 m.y. is manifested only to the south and east of the Kalkadoon‐Leichhardt complex, and including the Sybella Granite. The results may be further interpreted as lending support to the concept of a possible “metamorphic discontinuity” along the western flank of the Kalkadoon‐Leichhardt complex, postulated by Carter, Brooks and Walker; as suggesting possible contemporaneity of the Cliffdale Volcanics and the Argylla Formation; and as giving further evidence for the antiquity of stromatolites. Comparison with earlier work suggests that some deposits in this region may be contemporaneous with some of the Agicondian sediments of the Katherine‐Darwin area, and that the second tectonic period corresponds with the K‐Ar ages obtained on the Davenportian granites of Central Australia. 相似文献
8.
M. L. O'Flynn 《Australian Journal of Earth Sciences》2013,60(1):65-73
The closure of the Brisbane River to extractive dredging and the exhaustion or limitation of other sand sources have caused an industry shift to manufactured sand for concrete fine aggregates. Manufactured sand is generated in a purpose‐designed process; it is not recycled waste‐crusher dust. At present it is produced in 12 of the major hardrock quarries in southeast Queensland. To date companies have achieved only partial replacement of natural sands, to around 40% of the fine aggregate component in their concrete mixes. While improved technology and management will further reduce the amount of natural blend sand required, it is unlikely to be fully replaced in the foreseeable future. Although providing a solution to one problem, manufactured sand raises new environmental issues. The management of fine wastes is likely to become an important issue, as will the increased demand for natural fine sands to improve mix grading and workability. Diminishing supply from land‐based sources has resulted in increased applications for dredging of Moreton Bay, where enormous resources occur and low impact extraction may be possible. However, this prospect raises difficult environmental and land‐access issues for government decision makers. 相似文献
9.
The geochemistry of two deerite‐bearing meta‐ironstones from the Emo Metamorphics of Papua New Guinea suggests that they were deposited as metalliferous cherts enriched in manganese and iron by hydrothermal exhalative activity in an ocean ridge system. Subsequent blueschist facies metamorphism resulted in the formation of the assemblage deerite‐quartz‐albite‐iron oxides‐alkali amphiboles‐spessar‐tine‐stilpnomelane‐apatite, with calcium‐manganese carbonates in one specimen. Assemblages in associated metabasites suggest P‐T conditions of 7 kb at 320°C, which overlap with the P‐T field defined by one of the meta‐ironstones. Oxygen fugacity was probably an important control in determining variations in mineralogy and mineral chemistry. Preliminary data on the trace element geochemistry of associated metabasites are consistent with an ocean ridge environment for the formation of the meta‐ironstones. 相似文献
10.
S. Jaireth 《Australian Journal of Earth Sciences》2013,60(3):181-189
This paper presents the results of thermodynamic calculations on the solubility of gold and silver in low‐temperature, moderately saline, oxygen‐saturated fluids. Based on the solubilities of gold and silver it is argued that the quantity of gold transported by the fluids depends on the concentration of silver in the primary ores. In ores where the silver/gold ratio is high (1 to > 10), the fluids become saturated in silver and can not dissolve geologically significant concentrations of gold. In ores where the silver/gold ratio is low (< 1), the fluids remain undersaturated with respect to silver and are able to dissolve geologically realistic concentrations of gold and silver. The oxidized fluids start depositing gold and silver as they move downwards and are reduced by the Fe+2‐bearing minerals of the primary ores. The occurrence of gold in lateritic profiles can be explained by a prolonged process of interaction between the fluid and primary ores, during which gold and silver precipitate and redissolve selectively at the gradually advancing oxidation‐reduction interface. 相似文献
11.
The Tari‐Koroba district is at an altitude of about 1,500 m in the Southern Highlands of Papua in an imbricate province in which uplift and faulting occurred in Pliocene times. In the southeast of the area Miocene limestones are overlain by volcanic rocks erupted about 0.85 m.y. ago, as determined from K‐Ar measurements. These middle Pleistocene flows crossed the course of the Tagari River, damming its waters to form Lake Haibuga. Sediments accumulated in this and neighbouring basins. At one site near Pureni, diprotodontid remains were found; wood associated with the deposit gave a 14C age of 32,700 yrs B.P. Pollen from this fossiliferous horizon and from another section nearby (14C age of 38,600 yrs B.P.) indicate that the climate was cooler than at present and perhaps equivalent to that experienced at about 600 m higher elevation today. Pollen from stratigraphically lower samples indicate still colder conditions and may reflect a glacial phase in the highlands earlier than the last glaciation. 相似文献
12.
Hydrogen‐ and oxygen‐isotope analyses of biotite (19), sericite (8), chlorite (2), quartz (27), and total rocks (37) from the Panguna porphyry‐copper deposit on Bougainville Island, place important constraints on the origin of the hydrothermal fluids responsible for mineralization and alteration in the mine region. Early high‐temperature amphibole‐magnetite alteration resulted from magmatic‐hydrothermal fluids. Several lines of evidence indicate 500°C as a realistic average temperature for mineralization, development of quartz veins, and biotitization processes. On the basis of mineral isotope data, responsible fluids could represent either 18O‐shifted ground‐waters or magmatic‐hydrothermal fluids at submagmatic temperatures. Independent evidence, as well as total‐rock 18O data, support the magmatic‐hydrothermal model. Late‐stage sericitization processes probably resulted from fluids produced by 18O shifting of groundwaters during the evolution of the propylitic zone. Outermost quartz veins and biotitization conceivably resulted from fluids similar to those that caused sericitization, indicating that some interaction between relatively cool, 18O‐poor meteoric waters and the ore fluids occurred near the margins of the deposit. The origin of the chlorite‐sericite alteration cannot be resolved solely by isotope studies. 相似文献
13.
K‐Ar ages of biotite and hornblende from undeformed granodiorite plutons and of slaty and phyllitic rocks, ranging from prehnite‐pumpellyite metagreywacke to greenschist fades, have been determined in an attempt to define the age of orogenesis in the eastern part of the Nambucca Slate Belt. The plutons have K‐Ar ages of 226–227 m.y. (biotite) and 228–231 m.y. (hornblende) that provide a younger age limit for deformation. The lower grade metamorphic rocks yield a range of ages including some comparable with the depositional age of the rocks as indicated by fossils. Rocks of pumpellyite‐actinolite and greenschist facies give a more coherent group of ages which suggest orogenesis at about 250–255 m.y. Specimens of these latter rocks that have been affected by a later structural episode than that during which slaty cleavage formed, yield slightly older ages, which may result from the inclusion of minor amounts of environmental excess 40Ar. Support for the 250–255 m.y. age comes from previously determined radiometric ages from the western part of the Slate Belt, although the presence of granitic bodies perhaps as old as 289 m.y., some closely associated with high‐grade regional metamorphic rocks, may indicate the presence of additional earlier orogenic movements in this region. 相似文献
14.
The nomenclature of replacement deposits is reviewed in terms of two processes, namely those involving the reaction between: (a) carbonate and siliceous rocks and (b) carbonate and unusual solutions, commonly, but not always, related to granitoids. ‘Wrigglite’ skarn is an example of a replacement deposit produced by process (b). It is highly characteristic rock consisting of alternating light layers of fluorite ± other F‐rich minerals and dark layers composed usually of Fe‐rich minerals or, rarely, Be‐rich minerals. The layers formed parallel or sub‐parallel to fractures, which are now veins, by a Leisegang‐type diffusion process. Repeated periods of fracturing, with growth away from sequentially produced fractures, produced an apparently chaotic ‘wrigglite’ skarn. The skarn is invariably enriched in Fe, F, Sn, Be, W, Bi and Zn. For ‘wrigglite’ to form, fluorine must be greater than 9 weight percent in the rock, and the intrusion of a Sn‐leucogranite ('A‐type') high into the crust is needed. Recognition of ‘wrigglite’ is important because (1) in some areas it is an ore of Sn (Mt Bischoff, Tas.), rare earth metals (Bayan Obo, China) or Be (Lost River, Alaska); (2) it indicates a high‐level environment of emplacement of a Sn‐granitoid; and (3) it indicates clearly that intricate layering can be produced by a diffusional process and not only by primary sedimentation. 相似文献
15.
Geotechnical aspects of domestic on‐site effluent systems (septic tanks) and their impact on groundwaters are discussed and the limited relevant literature is reviewed. While there are few Australian case studies, the early stages of an ongoing study at Dodges Ferry, Tasmania, show a connection between shallow aquifer quality, number of residences and domestic on‐site wastewater disposal practices. Of 26 groundwater samples analysed, a number fail to meet established criteria for potable use. Most samples were highly or very highly saline. This renders them unpalatable and has an adverse impact on vegetation if the water is used for irrigation. Several samples had pH less than 6.0 and those taken from shallow wells were discoloured by leached soil organic matter. Elevated nitrate levels, an indicator of contamination by sewage effluents, were found at nine locations and these were usually associated with small clusters of residences. One very high sample was clearly contaminated by effluent from an adjacent on‐site wastewater disposal system. One odorous, black organic seep was found at the foot of the dunes backing a bathing beach and this gives cause for concern that failing on‐site wastewater disposal systems are contributory to reduced bathing water quality. Faecal coliforms and Escherichia coli were not found, even in samples with the highest nitrate concentrations, suggesting that residence time has been sufficient for bacterial die‐off. Contamination of shallow aquifers is greatest where there is a high density of residences with small lots. 相似文献
16.
Malcolm T. McCulloch William Compston Dereck Froude 《Australian Journal of Earth Sciences》2013,60(1-2):149-153
Sm‐Nd and Rb‐Sr isotopic data for Archaean gneisses from three localities within the eastern Yilgarn Block of Western Australia indicate that the gneisses define a precise Rb‐Sr whole rock isochron age of 2780 ± 60 Ma and an initial 87Sr/86Sr of 0.7007 ± 5. The Sm‐Nd isotopic data do not correspond to a single linear array, but form two coherent groups that are consistent with a c. 2800 Ma age of crust formation, with variable initial Nd. These results indicate that the gneiss protoliths existed as continental crust for a maximum period of only c. 100 Ma, and probably for a much shorter time, prior to the formation of the 2790 ±30 Ma greenstones. 相似文献
17.
Christopher Brooks 《Australian Journal of Earth Sciences》2013,60(2):457-469
Rb‐Sr isotopic age measurements relate emplacement of the Pieman and Meredith Granites (356 ± 9 and 353 ± 7 m.y., respectively), and the Bischoff and Renison Bell Porphyries (349 ±4 and 355 ± 4 m.y., respectively) to the Tabberabberan Orogeny. The genetic relationship of the Bischoff Porphyry to mineralization and the agreement between the age of this porphyry and the age of the adjacent Meredith Granite, strongly suggests that the Bischoff mineralization resulted from granite intrusion. The Pieman Granite is closely similar to the white Heemskirk Granite in displaying a high initial 87Sr/86Sr ratio (0.7354 ± 0.0018), feldspar discordance patterns and open system total‐rock behaviour. The high initial 87Sr/86Sr ratio is attributed to contamination during intrusion by Precambrian metasediments containing appreciable radiogenic strontium. A basic intrusion (McIvors Hill Gabbro) gave a pre‐Tabberabberan age (518 ±133 m.y.) and a high initial 87Sr/86Sr ratio (0.7132 ± 0.0031). 相似文献
18.
R. W. Page 《Australian Journal of Earth Sciences》2013,60(3-4):141-164
A detailed Rb‐Sr total‐rock and mineral and U‐Pb zircon study has been made on suites of Proterozoic silicic volcanic rocks and granitic intrusions, from near Mt Isa, northwest Queensland. Stratigraphically consistent U‐Pb zircon ages within the basement igneous succession show that the oldest recognized crustal development was the outpouring of acid volcanics (Leichhardt Metamorphics) 1865 ± 3 m.y. ago, which are intruded by coeval, epizonal granites and granodiorites (Kalkadoon Granite) whose pooled U‐Pb age is 1862 +27 ‐21 m.y. A younger rhyolitic suite (Argylla Formation) within the basement succession has an age of 1777 ± 7 m.y., and a third acid volcanic unit (Carters Bore Rhyolite), much higher again in the sequence, crystallized 1678 ± 1 m.y. ago. All of these rocks are altered in various degrees by low‐grade metamorphic events, and in at least one area, these events were accompanied by, and can be partly related to, emplacement of a syntectonic, foliated granitic batholith (Wonga Granite) between 1670 and 1625 m.y. ago. Rocks that significantly predate this earliest recognized metamorphism, have had their primary Rb‐Sr total‐rock systematics profoundly disturbed, as evidenced by 10 to 15% lowering of most Rb‐Sr isochron ages, and a general grouping of many of the lowered ages (some of which are in conflict with unequivocal geological relationships) within the 1600–1700 m.y. interval. Such isochrons possess anomalously high initial 87Sr/86Sr ratios, and some have a slightly curved array of isotopic data points. Disturbance of the Rb‐Sr total‐rock ages is attributed primarily to mild hydrothermal leaching, which resulted in the loss of Sr (relatively enriched in 87Sr in the Sr‐poor (high Rb/Sr) rocks as compared with the Sr‐rich rocks). 相似文献
19.
An ‘autochthon’ model for the tectonic development of Timor is suggested, based on observations of Palaeozoic‐Mesozoic relationships from a broad area of central East Timor, including:
-
(a) ‘allochthonous’ Permian rocks unconformable on metamorphic rocks
-
(b) ‘allochthonous’ Permian units interbedded with ‘autochthonous’ Permian units, and
-
(c) ‘autochthonous’ Triassic sediments stratigraphically overlying ‘allochthonous’ Permian rocks.
20.
Sufficient stratigraphic and radiometric data are now available to provide the basis for a time‐stratigraphic subdivision of the Precambrian in Australia. The data show that a major stratigraphic break occurred from about 2,600 to 2,300 m.y. and another at about 1,800 m.y., and that igneous activity was widespread from 2,700 to 2,600 m.y., and at about 1,800 m.y. and 1,500 m.y. Three largely unmetamorphosed rock sequences represent most of the time‐interval from 2,300 m.y., to the start of the Cambrian. The terms Archaean and Proterozoic are tentatively retained with a boundary dated at or before about 2,300 m.y. Time‐rock subdivision of the Proterozoic is proposed in terms of the three unmetamorphosed rock sequences deposited after 2,300 m.y. The oldest time‐rock unit is to be defined from the Hamersley Range area of Western Australia and is tentatively named the Lower Proterozoic ("Nullaginian") System with a base dated at about 2,300 m.y. The other units are the Carpentarian and Adelaidean Systems which have bases dated at about 1,800 m.y. and 1,400 m.y., respectively. The top of the Adelaidean System is defined by the base of the Cambrian. The boundaries between the proposed time‐rock units have ages comparable with those of boundaries between some overseas Precambrian subdivisions based on plutonic events. 相似文献